ES2260022T3 - SILENCER ACOUSTIC NOZZLE. - Google Patents

Abstract

An acoustic silencer nozzle for ventilation and exhaust fans. The nozzle provides at least two converging exhaust paths, each of which extend through an area that is adjacent acoustically absorbing media or resonating chambers. In this manner, the noise is reduced at the nozzle or outlet portion and provides a tight plume of high velocity discharge flow. Preferably, the nozzle has at least one opening that allows for ambient atmospheric air to mix with the exhaust gases at the outlet of the nozzle.

Description

Acoustic silencer nozzle.

Field of the Invention

The present invention relates in terms general to the nozzles for fans and, more particularly, to the high speed silencer nozzles for use with exhaust fans.

Background of the invention

The prior art devices have been designed to provide high pressure speed for the atmospheric air and other exhaust gases, as described, for example, in U.S. Pat. No. 4,806,076, assigned to Andrews, and U.S. Patent No. 5,439,349, assigned to Kupferberg. These exhaust fans are usually mounted on the roof surfaces of buildings and are used to expel gases as high as possible above the line of the roof of a building to ensure effective dissolution of gases within the largest possible air volume environmental and its dispersion in a large area with maximum dissolution. The U.S. Patent fan No. 4,806,076 has a nozzle in which are two convergent flow paths delimited through two respective aisles. The walls that form these aisles are formed as sectors of conical sections. A wind band is provided at one end of the two aisles in the outputs thereof to provide an air induction fresh that mixes with the extraction gases coming from the Two aisles

Conventional exhaust fans for moving large volumes of air often generate high levels of noise which is not desirable. Consequently, it has been proposed a wide variety of fan muffler equipment so that they absorb fan noise, reducing, so Therefore, fan noise to an acceptable level. Without However, conventional silencers are used in a part of the fan device and do not control the noise in the nozzle or part of the outlet. These silencers Conventionals are not desirable for several reasons, among others, because they lead to even increase in the total height of the device ventilation and are limited to a distribution speed of relatively low air (on the order of less than about 15.24 m / second (3000 feet / minute) which is when they are effective (i.e. when they provide maximum attenuation without themselves generate no significant noise). GB 984,817 presents a silencer device for a stream of propelled gas by a fan that works in a duct in which the wall of the duct that is in the vicinity of the fan is provided with perforations and surrounded with a blanket of the material sound absorbing GB 1,166,843 presents a diffuser gas blower comprising a conduit in which an absorbent acoustic comprising filaments of knitting or material tissue formed inside the absorbent in layers of the mantle and is arranged around the outer surface of the duct. For the therefore, there is a need for a device that controls noise in the nozzle or the outlet part to reduce the height of the fan or other device that provides a relatively high air distribution speed without adding significant pressure To the system.

Summary of the Invention

The present invention relates to a nozzle Selector acoustics for devices such as devices ventilation and extraction. The nozzle provides at least two Extraction aisles, each extending through the area which is close to any absorbent acoustic medium or chambers of resonance. In this way, the noise in the nozzle or in the outlet part and a waterproof air mass of a high speed flow. Preferably, the nozzle has minus an opening that allows ambient air to mix with Extraction gases at the nozzle outlet.

In accordance with an embodiment of the present invention, the nozzle of the acoustic silencer comprises: sections, first and second, of the outer wall, formed, approximately, each, as a partial and conical section, being concave, one in relation to the other, or cylindrical or right on the interior walls, being located opposite of the other, comprising, at least a part of each of the first and second section of the outer wall a material perforated, at least the first upper air outlet and by at least the second upper air outlet to release the gases of extraction thereof; the first outer coating arranged in the vicinity of the part of the first section of the outer wall comprising perforated material to delimit the first closed outer space; the second coating exterior arranged in the vicinity of a part of the second outer wall section comprising perforated material to delimit the second closed outer space; the first interior wall section located in a spaced relationship in relationship with the first section of the outer wall, comprising at least a part of the first section of the inner wall, the perforated material, the first section being of the inner wall approximately formed as a section partially conical, cylindrical or right being convex or right towards the first section of the outer wall to delimit so minus the first extraction flow passage between them adapted to receive the extraction gases and guide them to its release up through the first upper exit from air; the first inner lining arranged in the proximity of the part of the first section of the inner wall comprising the perforated material to delimit the first closed interior space; the second section of the inner wall located in spaced relation to the second section of the outer wall, at least a part of the second section of the inner wall comprising a perforated material, the second section of the inner wall formed as a section partially conical, cylindrical or right being convex or right towards the second section of the outer wall to delimit so minus a second aisle of the extraction flow between them, adapted to receive the extraction gases and guide them to release them up through the second upper outlet of the air, the first and second path of the flow being convergent extraction; the second inner lining arranged in the vicinity of the section part of the second section of the inner wall comprising the perforated material (or other similar material such as expanded metal or foam) to delimit the second closed interior space; acoustic absorbent media arranged in the first and second closed outer space and the first and second closed interior space; at least the first extreme wall extending from the first section inner wall to the first section of the outer wall to enclose the gases that pass between them within the first extraction flow path, the first flow path of extraction going through the first outer closed space and the first enclosed space; at least one wall of the second end extending from the section of the second inner wall to the second section of the outer wall to delimit the gases that pass between them within the second flow of the path of extraction, the second path of the extraction flow through the second outer closed space and the second inner space locked up absorbing noise through the sections that comprise perforated material (or other similar material such as expanded metal or foam) inside the acoustic media absorbents

Brief description of the drawings

The text presented previously and others aspects of the present invention will be more understandable having analyzed the detailed description of the invention taken in consideration in conjunction with the accompanying drawings. With the In order to illustrate the invention, in the drawings a realization that is currently preferred, however it should be of understanding that the invention is not limited to the methods and specific instrumentations that are presented. In the drawings:

Figure 1 is a front plan view of an acoustic silencer nozzle in accordance with the present invention incorporated into the extraction fan;

Figure 2 is a cross-sectional front view of the silencer nozzle of Figure 1;

Figure 3 is a cross-sectional side view of the silencer nozzle of Figure 1 taken along the lines 3 - 3 of Figure 1:

Figure 4 is a front plan view of the acoustic silencer nozzle according to the present invention which shows the use of a wind band located around the same;

Figure 5 is a cross-sectional view of a acoustic silencer nozzle of the present invention as is shown in Figure 1 along lines 5-5;

Figure 6 is a cross-sectional view of a exemplary acoustic silencer nozzle of the present invention as shown in Figure 1 along lines 6 - 6;

Figure 7 is a front plan view of the alternative embodiment of the acoustic silencer nozzle of the present invention showing an embodiment, located so remote, of the fan drive means;

Figure 8 is a front elevational view of a exemplary acoustic silencer nozzle incorporated into another extraction fan according to the present invention;

Figure 9 is a vertical cross-sectional view. taken along line 9-9 of Figure 8;

Figure 10 is a cross-sectional view, fragmentary and vertical, of a detail of the embodiment shown in  Figure 8; Y

Figure 11 is a cross-sectional view and horizontal taken along line 11 - 11 of Figure 10.

Description of exemplary embodiments and the best methods of its use

The present invention provides a nozzle acoustic silencer for use with devices such as fans  of extraction and ventilation. The nozzle provides at least two convergent extraction paths, each extending through of the area that is located in the vicinity of the environment acoustically absorbent or resonant chambers. In this way, the noise remains reduced at the nozzle or at the outlet and provides a Waterproof air mass of high speed flow. Preferably, the nozzle has at least one opening that allows atmospheric air to mix with gases from extraction at the outlet of the nozzle.

\hbox{acústica 18.}

The first exemplary embodiment according to the present invention is shown in Figure 1. The extraction fan apparatus, such as one of radial acoustic overload, mixed flow, centrifugal or an axial extraction fan, includes a main housing 10 having a fan housing 12 in the lower section thereof and an acoustic silencer nozzle 18 located above the fan housing 12 and extending upward therefrom. The fan housing 12 delimits the fan inlet 14 adapted to receive the gases for its extraction from above and an outlet of the fan 16 that allows the movement of the gases upwards from the fan housing 12 and its introduction into the silencer nozzle

 \ hbox {acoustic 18.} 

The acoustic silencer nozzle 18 defines the first section of the outer wall 20 and the second section of the outer wall 22 being the two, usually conical sections, concave, cylindrical or right, one with respect to the other. The nozzle acoustic silencer 18 also delimits the first upper outlet of air 24 and the second upper air outlet 26 in the part highest of it. A section of the passive area 28 that delimits the passive area chamber 48 is located between the first section of the outer wall 20 and the first upper air outlet 24 and the second section of the outer wall 22 and the second exit upper air 26. The passive area supplies the air for mix it through induction into contaminated air this being extracted through the two upper outputs.

The section of the passive area 28 delimits the first section of the inner wall 30 having a conical shape, cylindrical or right section that is convex or right, oriented out and towards the first section of the outer wall 20. The first path of the extraction flow 32 is delimited between the first section of the inner wall 30 and the first section of the outer wall 20. Similarly, the section of the passive area 28 delimits the second section of the inner wall 34 that is formed as conical section and is convex, oriented outward and found in spaced relation to the second section of the outer wall 22 to delimit the second path of the flow of extraction 36 located between them.

At least a part of the first wall outer 20 and the first inner wall 30 comprise a material perforated, such as steel, fiberglass or perforated polypropylene. Similarly, at least a part of the second wall outer 22 and the second inner wall 34 comprise the material Perforated.

The first and the second outer covering 70, 80 are arranged in the vicinity of the section of the outer walls 20, 22 comprising the perforated material. The outer liners 70, 80 and perforated sections have the respective spiced partitions between them provided in this way the respective enclosed spaces exteriors or chambers 75, 85. The exterior enclosed spaces 75, 85 contain, disposed therein, an acoustic material absorbent 77, 87, such as stainless steel wool or a material of fiberglass or any other acoustically treated medium. From alternatively, the enclosed outdoor spaces 75, 75, 85 They can each be a resonance chamber. The spaces exterior enclosures or chambers 75, 85 are closed in both extremes While the air moves down the paths of the extraction flow 32, 36, the noise is absorbed through the perforations on the surfaces of the outer walls 20, 22 inside the acoustic filler material 77, 87.

Similarly, interior cladding 90, 95 are arranged in the vicinity of the sections perforated on the interior walls 30, 34, respectively. The inner liners 90, 95 and perforated sections have respective partitions spaced between them providing, in this way, the respective spaces or interior chambers enclosed 92, 97. Inside the enclosed interior spaces 92, 97 an absorbent acoustic material 94, 99 is arranged, such as plastic, coated or galvanized steel, stainless steel, mineral wool or fiberglass material or any other material acoustically treated and may also include a wrapper or chemically resistant barrier such as mylar, polyurethane or material similar to prevent the existence of pollutants from extraction, moisture or mold from accumulation in the acoustic material or cavity. Alternatively, the spaces enclosed interiors 92, 97 may each constitute a resonance chamber The enclosed and interior spaces or chambers 92, 97 are closed at each end. While the air moves down the paths of the extraction flow 32, 36, the noise is absorbed through the perforations on the interior wall surfaces 30, 34 within the material of acoustic padding 94, 99.

Preferably, the holes in the section perforated constitute about 20 to 75 percent of the area of it and have approximately 2.28 to 25 mm. (3/32 up to 1 inch) in diameter and the perforated section covers so minus about 50 to 100 percent of the length of the outer and inner walls.

The first extreme wall 38 that can adopt the shape of two end walls 58 may be located extending between the first section of the inner wall 30 and the first outer wall section 20. These end walls are shown in Figures 5 and 6 and in the definition of the first extraction flow path 32. Similarly, the second extreme wall 40 that can take the form of two second walls ends 60 may be located extending from the second inner wall section 34 to the second wall section exterior 22 to facilitate the delimitation of the second path of the extraction flow 36.

To facilitate the flow of air to be extract through the first and second path of the flow of extraction, a fan 42 may preferably be located inside the fan housing 12. The fan is connected operatively with respect to the driving unit of the fan 54 to control its operation. Unit fan drive 54 may be located inside the chamber of the passive area 48 or it may be located outside the main housing 10 of the present invention as shown in Figure 7 or be completely below the nozzle section. In the configuration shown in Figure 7, the transmitter unit by belt 56 may be included and located within the section of passive area 28 and can be operatively secured with respect to the driving unit 54 which in itself may be secured with respect to the outside of the main housing 10.

To facilitate mixing of the extraction gas with environmental gases, wind band 44 may be located vertically extending usually in relation parallel to the upper end of the silencer nozzle acoustic 18. Preferably, the wind band 44 is located at a spaced relationship to the outer walls of the nozzle of the acoustic silencer 18 by means of the support of the wind band 46. In this way, when gases are extracted to through the first upper air outlet 24 and the second outlet upper air 26, the air will be induced to flow as shown in Figure 4 by means of arrows 62. Also, the air will also be induced to flow from the passive area chamber 48 up as shown by arrow 63 inside the gases contaminated that are being extracted through the two exits superior to facilitate mixing right there. Preferably the ambient air mixes with the extraction air immediately after the movement of the gases that pass abroad through the upper exits 24 and 26. The wind band 44 protect the contracted section produced by convergent flow (air mass) from the primary extraction aisle.

The cross section shown in Figure 3 is perpendicular through a plane that extends so horizontal with respect to the cross section shown in Figure 2. As such, the shape of the path of the first extraction flow 32 and the second path of the extraction flow 36 of Figure 2 It is shown as parallel and vertical extending so tilted in in the direction of the passive area. In the Figure 3 shows the view along lines 3 - 3 of the Figure 1 and as such the outer surface of the first and the Second extreme wall 38 and 40 is shown right there. These walls show a configuration with the first intermediate point 50 located on the outer wall of the first end wall 38 and the second intermediate point 52 located on the outer wall of the second extreme wall 40. In this way, we can see that the section transverse of the extraction flow paths is as is shown in Figure 2 when it passes through the central part of the same and has the tendency to assume the shape of the surface exterior of the first and second end wall 38 and 40 shown in Figure 3 towards the outer peripheral edges of the first and of the second path of the extraction flow, 32 and 36. The use of the conical sections for the walls that delimit the paths of the extraction flow is important in view of the high volume of the air flow with which such extraction systems are found of acoustic overload.

The exemplary apparatus of the present invention it can include two or more vertical flow paths and of this form two or more upper outlets of the contaminated air. The present invention basically defines one on one side and one on the other side with the passive area between the two. Each of these outputs can be divided into multiple sections such that any number of individual and higher flow paths can be defined as located circumferentially around the passive area

During operation of the muffler of the present invention, the primary fluid stream (e.g., exhaust gases) moves at the speed of at least about 10-16 m / second (2000 ft / min) (relative to the fluid in the atmosphere) and preferably rises to around 38 - 53 m / second (6600 ft / minute) The movement of this primary fluid stream determines the aspiration such that the secondary fluid stream is removed from the ambient fluid of the
atmosphere.

It should be taken into account that the paths of extraction 32, 36 converge with the purpose of maintaining the mass of waterproof exhaust air which can create a stream of air of the order of about 33.5 m (110 ft) in diameter moving at the speed of about 1.27 m / second (250 feet / minute) in the still air. This fact helps to dilute the tributary or smoke before its release into the atmosphere, minimizing, in this way, pollution problems with a extremely high efficiency

Another exemplary extractor fan comprising an acoustic silencer nozzle in accordance with the present invention is described with respect to Figure 8. The apparatus 110 has a base 112 intended to be mounted on the roof, a centrifugal fan wrap 114 mounted on base 112 and an inlet duct 116 extending to one side of the wrapper 114 from inside the building (which is not shown). An extraction chimney or nozzle 118 and on it extraction chimney a ring 120 of frustoconic form is mounted on top of the centrifugal envelope of the fan 114.

Similar to the realizations presented previously, a part of the walls, interior and exterior, of the chimney or nozzle 118 comprises a perforated material, such as the perforated steel, fiberglass or polypropylene. The first and the second wrapper 70, 80 are arranged in the vicinity of the section of the outer walls comprising the material Perforated. Outer wrappers 70, 80 and sections perforated have the respective partitions spaced between the themselves, thus providing the respective spaces or cameras, exterior and enclosed, 75, 85. The exterior spaces enclosed 75, 85 have disposed within them a material acoustic absorbent 77, 87, such as plastic, coated steel or Galvanized, stainless steel, mineral wool or fiber material of glass or any other acoustically treated medium and also may include a chemically resistant wrapper or barrier, such as mylar, polyurethane or similar material to prevent extraction contaminants, moisture or mold resulting from the accumulation in the acoustic material or cavity. Alternatively, the enclosed outdoor spaces 75, 85 may constitute, each, A resonance chamber The spaces or outer chambers enclosed 75, 85 are closed at each end. When the air gets moves down the extraction flow paths, the noise is absorbed through perforations on surfaces of the outer walls inside the acoustic filling material 77, 87.

Similarly, the inner wrappers 90, 95 are arranged in the vicinity of the perforated sections  On the interior walls. The inner wraps 90, 95 and perforated sections have respective spaced partitions between them, thus providing the spaces or Interior and enclosed chambers 92, 97. Interior spaces enclosed 92, 97 have a material arranged there acoustic absorbent 94, 99, such as plastic, coated steel or Galvanized, stainless steel, mineral wool or fiber material glass or any other acoustically treated medium and may also include a chemically resistant wrapper or barrier such as mylar, polyurethane or similar material to prevent extraction contaminants, moisture or mold from the accumulation in the acoustic material or cavity. Alternatively, the interior enclosed spaces 92, 97 may constitute, each One, a resonance chamber. The spaces or interior chambers locked 92, 97 are closed at both ends. While the air moves down the flow paths of extraction, the noise is absorbed through the perforations in the interior wall surfaces inside the material acoustic padding 94, 99.

Base 112 includes a frame 122 on which a motor 124 is mounted. Stem 126 is seated in the bearing brackets 128 mounted on frame 122 and extends inside the box 132 in the form of a cantilever. Stem 126 is propelled by a drive belt 130 that comes from the engine 124. As shown in Figure 9, the stem 126 is mounted on a centrifugal impeller 138 that has multiple vanes of the fan that revolve around the stem 126.

Case 114 includes a spiral groove 132 that surrounds impeller 138 and is interrupted by the discharge port 144. The spiral groove includes a cutout 134 near the port of download 144. Box 114 also includes the side walls parallel 136. The input port 140 is defined in the wall of one side 136 of the box 114, and the connection tabs 142 are provided to secure the input port 140 with the conduit of entry 116.

In this way, the waste gases that contain extraction contaminants included in the air coming from the building through conduit 116 enter the box 114 in axial relation relative to impeller 138 and the flow of air is accelerated through the discharge port 144. A diffuser tube 146 is mounted on the discharge port 144 and communicates with the same. The diffuser tube 146 is, in turn, connected to the duct  forked 148 by means of connecting tabs 149. The conduit forked 148 includes corridors 150 and 152 which generally they are parallel, although, in fact, they converge slightly towards the exit. A central opening 155 is formed by means of the interior flat walls 154 and 156 delimiting the corridors 150 and 152, respectively.

As shown in Figures 10 and 11, the output ports 158 and 160 are delimited at the end of the bifurcated duct 148, communicating with the aisles 150 and 152, respectively. An annular ring 162 extends around the upper end of the bifurcated duct 148. The ring 164 is formed between ring 120 and ring 162.

During operation, impeller 138, driven by engine 124, it will remove the exhaust gases from the building that contains the existing pollutants in the air to through conduit 116 and then take them up inside the chimney or nozzle 118 first passing through the diffuser and then through double corridors 150 and 152. The location of the box 114 and, in particular, the groove orientation spiral 132 relative to the chimney or nozzle 118, allows even the air flow distribution within the diffuser and through corridors 150 and 152. Contaminated gases are extracted through of output ports 158 and 160 at a relatively high speed high and will cause ambient air to be induced within the ring 164 to mix with the contaminants in the air and, therefore, dilute the extraction.

The present invention provides the advantages of a smaller chimney height and safety increased The present invention minimizes the loss of static pressure in the system and increases noise attenuation in comparison with the usual silencer at a higher speed. The The present invention also provides greater accessibility to interior parts (for example, the engine) for inspection.

It is planned that the nozzle silencer of the The present invention can be used with any type of exit. The fan, motor and drive can be located anywhere. The present invention can be used with fans of different types or other appliances which emit the exhaust gases at the speed above around 10.6 m / second (2000 feet / minute).

Although the present invention is presented and described in this document with reference to certain specific embodiments, however it is not intended that this Invention is limited to the details shown. Rather be they can introduce several modifications to the details within the scope and range of equivalents of the claims without get away from the present invention.

Claims (21)

1. A compound acoustic silencer nozzle from: the first section of the outer wall (20) and the second section of the outer wall (22), each formed approximately as a partial conical section, being concave, one with respect to the other, and being located opposite, a with respect to the other, at least a part of each of the first and second sections of the outer wall (20, 22) comprising a perforated material, at least a first exit upper air (24) and at least a second upper outlet of the air (26) to release the exhaust gases from right there; the first outer covering (70) arranged in the vicinity of the first section of the outer wall (20) comprising the perforated material to delimit the first space enclosed exterior (75); the second outer covering (80) arranged in the vicinity of the part of the second outer wall (22), a section comprising the perforated material to delimit the second outer space enclosed (85); the first section of the inner wall (30) located in a spaced relationship with respect to the first mentioned outer wall section (20), at least a part of the first section of the inner wall comprises a material perforated, said first section of the inner wall being approximately formed as one of the sections partially conical, cylindrical and right, being convex or right towards the said first section of the outer wall (20) to delimit by at least a first extraction path (52) between them, adapted to receive the extraction gases and guide them for upward release through the first upper outlet of the air (24); the first inner lining (40) arranged in the vicinity of the part of the first sections of the wall interior (30) comprising the perforated material to delimit the first enclosed interior space (92); the second section of the inner wall (34) located in a spaced relationship with respect to the said second outer wall section (22), at least a part of the second section of the inner wall (34) comprises a material perforated, said section of the inner wall (34) being approximately formed as one of the sections partially conical, cylindrical and right, being convex or right towards the  cited second section of the outer wall (22) to delimit by at least a second path of the extraction flow (36) that is found between them, adapted to receive the gases of extraction and guide them for release upwards through said second upper air outlet (26), being convergent  the first and second path of the extraction flow; the second inner lining (95) arranged in the vicinity of the part of the second section of the wall interior (34) comprising the perforated material to delimit the second enclosed interior space (97); acoustically absorbent media (77, 87, 94, 97) arranged in the first and second outer spaces (95, 85) and the first and second inner space enclosed (92, 97); at least a first extreme wall (35) extending from said first section of the inner wall (30) to said first section of the outer wall (20) to delimit the gases passing between them within said first extraction flow path (32), said first extraction flow path (32) passes through the first enclosed outer space (75) and the first enclosed interior space (92) to absorb the noise through the sections comprising the perforated material within the acoustically absorbent means (79,

 [94]; Y} 

at least a second extreme wall (40) that extends from said second section of the inner wall (34) to said second section of the outer wall (22) for delimit the gases that pass between them within the aforementioned extraction flow path (36), said second path of the extraction flow (26) passes through the second outer space enclosed (85) and the second inner space enclosed (97) to absorb noise through the sections that comprise the perforated material within acoustically absorbent media (87, 99). 2. The nozzle according to claim 1, in which the perforated material can be steel, fiberglass and polypropylene. 3. The nozzle according to claim 1, in which the associated and absorbent acoustic medium (77, 87, 94, 99) comprises one of the following materials: plastic, steel coated or galvanized, stainless steel, mineral wool and fiber of glass. 4. The nozzle according to claim 1, in which the associated and absorbent acoustic medium (77, 87, 94, 99) also includes a resistant wrapper or barrier chemically 5. The nozzle according to claim 1, in which the associated and absorbent acoustic medium (77, 87, 94, 99) comprises at least one resonance chamber. 6. The nozzle according to claim 1, in which the holes in the perforated section constitute around 20 to 75 percent of the area of it. 7. The nozzle according to claim 1, in which the perforated section covers at least about the 50 to 100 percent of the length of the outer walls and interiors (20, 22, 30, 34). 8. A compound extractor fan apparatus from: (a) the main housing (10) comprising: a fan housing (12) that delimits the fan inlet (14) to receive the air that is going to remove and a fan outlet (16) to expel the air that has been extracted; Y an acoustic silencer nozzle (18) according with claim 1 located immediately above said fan housing (12), said acoustic silencer nozzle (18) being in fluid communication with said housing of the fan (12) through said fan outlet (16) to receive the extraction gases from there for your expulsion; in which said first path of the flow of extraction (22) is adapted to receive the extraction gases from the aforementioned fan outlet (16) and guide them to release them up through the said first exit upper air (24); in which the said second flow path extraction (36) is adapted to receive gases from extraction from said fan outlet (16) and guide them to release them up through the second cited upper air outlet (26) and (b) a fan (42) located within the said fan housing (12) and adapted to remove air for removal through said fan inlet (14) and expel the extraction air through said outlet of the fan (16) within said first path of the flow of extraction (32) and said second path of the extraction flow (36). 9. An exhaust fan apparatus according with claim 8, wherein said first section of the inner wall (30) is inclined upwards and inwards in address of said first section of the outer wall (20) to narrow the said first path of the extraction flow (32) to a smaller lateral dimension in the narrow area thereof and in which said second section of the wall interior (34) is inclined upwards and inwards in address of said second section of the outer wall (22) in order to narrow the said second path of the flow of extraction (36) to a smaller lateral dimension in the area top of it. 10. An exhaust fan apparatus according to claim 5, wherein said first section  of the outer wall (20) is inclined upwards and towards inside in the direction of said first section of the wall interior (20) in order to narrow the said first path of the extraction flow (32) to a smaller lateral dimension in the upper area thereof and in which said second section of the outer wall (22) is inclined upwards and inwards in the direction of the second section of the inner wall (34) to narrow the said second path of the extraction flow (26) to a smaller lateral dimension in the upper area of the same. 11. An exhaust fan apparatus according with claim 8 further including a wind band (44) located circumferentially around said first upper air outlet (24) and said second upper outlet of the air (26) and the upper part of said silencer nozzle acoustic, said wind band (44) extends vertically and in spaced relationship with respect to the upper end of the aforementioned acoustic silencer nozzle to induce gas flow environmental from below to mix and dilute gases which are extracted from the said first upper air outlet (24) and said second upper air outlet (26). 12. An exhaust fan apparatus according with claim 11 further including a band support of wind (46) secured with respect to said nozzle acoustic silencer and attached with respect to the aforementioned band of wind (44) to retain it in a spaced relationship with the aforementioned acoustic silencer nozzle. 13. An exhaust fan apparatus according with claim 8 which further includes an area camera passive (28) located between said first path of the flow of extraction (22) and said extraction flow path (36). 14. An extractor fan apparatus according to claim 8 wherein said first section of the outer wall (20) and said first section of the inner wall (30) are vertically parallel, relative to each other, to delimit said first path of the extraction flow (32) of constant lateral dimension, said first section of the outer wall (20) and said first section of the inner wall (30) being inclined upwards and inwards and where said second section of the outer wall (22) and said second section of the inner wall (34) are vertically parallel, relative to each other, in order to delimit the said second path of the extraction flow (36) of lateral dimension constant, being inclined upwards and inwards, said second section of the outer wall (22) and said second section of the wall

 \ hbox {interior (34).} 

15. An exhaust fan apparatus according with claim 8 wherein at least one of (1) said first section of the inner wall (30) is right so linear and vertical and in which the said first section of the wall exterior (20) is vertically arched with respect to it and (2) said second section of the inner wall (34) is right of linear and vertical manner and in which the said second section of the outer wall (22) is vertically arched with respect to the same. 16. An exhaust fan apparatus according with claim 8 further comprising at least one of the drive units (54) and the belt drive unit (56) operatively connected to said fan (62) within said fan housing (12) in order to control the operation of it. 17. An extractor fan apparatus that it comprises a housing that has a top part and a part bottom, in which the bottom includes a box with the spiral slot of the centrifugal fan (44), the box with the spiral groove (114) has parallel side walls (136), a stem (126) that extends inside the box normally with respect to the side wall (156) and mounted an impeller (128) for rotation within it, engine means (124) for actuate the stem (126), an input port (110) provided axially with respect to the fan shaft on the wall side of the box (44), a discharge port (144) that is extends from the spiral groove, the first tubular part and diffuser (146) that communicates with the download port of the fan (144) and the second tubular part (148) extending upwards from the first tubular part (146), the second part tubular (148) comprising the silencer acoustic nozzle of the claim 3 and being forked to provide at least two aisles (150, 152) that generally have parallel axes usually in normal relation to the fan shaft (126) and where the axes of the aisles (150, 152) are in a plane which is parallel to the axis of the fan, each of the two aisles (150, 152) being delimited by the inner wall section (154, 156) and the section of the outer wall where noise passes to through the sections comprising the perforated material inside of acoustically absorbent media (77, 87, 94, 99). 18. A ventilated extractor apparatus as is defined in claim 17, wherein the second part Tubular (148) includes a pair of spaced ports (158, 160) corresponding to the two aisles (150, 152) and a ring (162) surrounds the second tubular part (148) at the level of the ports of exit (158, 160) to form a ring (164) right there and where the ambient air is induced through the ring (164) to mix with the gases that are extracted from the hallway. 19. An exhaust fan apparatus according with claim 18, wherein the second tubular part (148) it has the frustoconic cross section but includes a space central free (155) defined by the elements of the opposite wall flat (154, 156) that delimits the two respective corridors (150, 152). 20. An exhaust fan apparatus according with claim 19 wherein the diffuser tube (146) is a tube inverted frustoconic that extends from the discharge port output (144) of the box with the spiral groove (114). 21. An exhaust fan apparatus according with claim 17 wherein the plane containing the axes of the aisles (150, 152) also contain the shaft of the stem of the fan (126).